KR101341709B1 - Method of constructing prestressed girder using segmented girder and prestressed girder using same - Google Patents

Abstract

The present invention relates to a method for manufacturing a prestress girder for bridges using a segmental girder, and a prestress girder constructed by the first segment, the first segment in which a plurality of through holes are formed in the longitudinal direction and the compression prestress is introduced by the first tension member. With girder; A pair of second segment girders having a plurality of through holes aligned with at least a portion of the through holes of the first segment girder and arranged on both sides of the first segment girder; The first segment girder and the pair of second segment girder are arranged so as to be tensioned to introduce a compression prestress to the first segment girder and the pair of second segment girder while the first segment girder and the one It consists of a second tension member that joins a pair of second segment girders so that a large prestress is introduced at the center portion and a smaller prestress at both ends to meet the stress state acting during the bridge's common use only by connecting the segment girder. The present invention provides a prestress girder and a manufacturing method thereof, by which the introduction amount of the compression prestress can be adjusted while implementing construction convenience.

Description

Method of manufacturing prestressed girder for bridges using segmental girder and prestressed girder constructed by the construction {METHOD OF CONSTRUCTING PRESTRESSED GIRDER USING SEGMENTED GIRDER AND PRESTRESSED GIRDER USING SAME}

The present invention relates to a method for manufacturing a bridge girder using a segmental girder and to a construction girder, and more particularly, in accordance with the stress state acting in common in the bridge in the production of long span girders by connecting the segment girder The present invention relates to a method for manufacturing a bridge girder using a segmented girder into which prestress is introduced, and a girder constructed thereby.

In general, precast concrete girder manufactures precast concrete blocks in a factory, then transports the precast concrete blocks to the site to arrange the precast concrete blocks in the longitudinal direction, and then to the plurality of longitudinally arranged precast concrete blocks. Compression prestress is introduced into a number of precast concrete blocks by inserting a tension member into the sheath tube of the block to fix the tension.

Since the precast concrete girder is constructed in the field using precast concrete blocks made in advance in the factory, it is possible to obtain an advantage of reducing the time required to manufacture the concrete girder on the site. However, when the girder is manufactured using the precast concrete block, the prestress is introduced at a time by connecting a plurality of precast concrete blocks by the tension material penetrating in the longitudinal direction. There was a limit.

In order to solve the conventional problems as described above, the construction using the segment girder while introducing such that the compression prestress corresponding to the stress state acting during the operation of the bridge in the production of the prestress girder by connecting the segment girder An object of the present invention is to provide a method of manufacturing a prestress girder for bridges and a prestress girder constructed thereby.

Through this, the present invention is able to introduce a higher prestress at the center portion and a lower prestress at both ends to connect the segment girder with the length of the span to match the stress state acting in common.

The present invention has been drawn to achieve the above object, the first segment girder, a plurality of through holes are formed in the longitudinal direction and the compression prestress is introduced by the first tension member; A pair of second segment girders having a plurality of through holes aligned with at least a portion of the through holes of the first segment girder and arranged on both sides of the first segment girder; The first segment girder and the pair of second segment girder are arranged so as to be tensioned to introduce a compression prestress to the first segment girder and the pair of second segment girder while the first segment girder and the one Provided is a prestress girder made of segmented girders including a second tension member that couples a pair of second segmented girders.

This is by tension-fixing the second tension member penetrating the first segment girder and the second segment girder in a state in which a pair of second segment girder is arranged on both sides of the first segment girder where the prestress is introduced by the first tension member. By introducing the prestress into the first segment girder and the second segment girder together, the first segment girder positioned at the center of the girder to be synthesized is introduced with compression prestress by the first tension member and the second tension member, and the outer side of the center portion of the girder Compression prestress is introduced into the second segment girder only by the second tension member, so that a larger compression prestress can be introduced in the center of the girder while interconnecting the segment girder to produce the girder.

In this way, as a larger compression prestress is introduced at the center of the girder and smaller compression prestress is introduced at both sides thereof, when the prestress girder manufactured as described above is installed in the bridge, the load acting largely at the center of the span is more effectively applied. I can support it. In addition, in the prior art, in order to support a load acting largely in the center portion of the span, compression prestress was required to be largely introduced over the entire length of the girder. In addition to the problem of introducing an inefficient prestress, which introduces a large amount of prestress unnecessarily, an excessively large compression prestress is introduced at both ends of the girder, thereby solving the problem of damaging the girder.

At this time, the first segment girder is not necessarily made of only one segment girder, it may be made by the two or more segment girder are arranged in series according to the length of the span center portion of the bridge. In addition, the configuration in which the compression prestress is introduced into the first segment girder as the first tension member may be introduced in a pretension manner by leaving the first tension member in a tensioned state at the time of manufacturing the first segment girder, or manufacturing the first segment girder. Thereafter, the first tension member may be inserted into the sheath tube installed therein, and then may be tension-fixed and introduced into the post-tension method.

At this time, the first tension member is used to introduce prestress to the first segment girder located in the center portion of the prestress girder to which a plurality of segment girders are connected. In order to more effectively cancel this tensile stress, the first tension member, which introduces the compression prestress at the center of the girder, is located on the lower side with respect to the neutral axis of the first segment girder as compared to the second tension member.

Meanwhile, as described above, the compression prestress may be introduced in two stages by the first segment girder (including the segment segment girder) and the second segment girder (including the segment segment girder). In addition, according to another embodiment of the present invention, a plurality of through holes aligned with at least a portion of the through holes of the first segment girder and the second segment girder are formed therethrough, and arranged on both sides of the second segment girder. A pair of third segment girder; The first segment girder, the pair of second segment girder, the pair of third segment girder are arranged to penetrate and tensioned the first segment girder, the pair of second segment girder, the pair of It may further comprise a third tension member for coupling the pair of second segment girder and the pair of third segment girder while introducing the compression prestress to the third segment girder.

In this way, the compression prestress is introduced into the first segment girder by the first tension member, the second tension member, and the third tension member, and the second segment girder introduces the compression prestress by the second tension member and the third tension member. Compression prestress is introduced into the girder by the third tension member, so that it is possible to gradually introduce a larger compression prestress at the center part while interconnecting the first segment girder, the second segment girder and the third segment girder.

Similarly, the second tension member may be spaced further downward from the neutral axis of the first segment girder than the third tension member. The third segment girder may be formed of two or more segment girder.

On the other hand, the prestress girder configured as described above may be a girder made by connecting the precast concrete segment girder made of concrete as the main material. According to another embodiment of the present invention, the prestress girder configured as described above may be a girder formed by connecting a steel girder and a steel composite girder to which casing concrete is synthesized. At this time, the tension member such as the first tension member and the second tension member for introducing the compression prestress may be disposed in the casing concrete so as to effectively cancel the tensile stress acting in common.

On the other hand, the present invention, the first steel pipe segment girder is formed in both ends of the first steel pipe diaphragm formed through a plurality of through holes; A second steel pipe diaphragm having a plurality of through holes formed in alignment with at least a part of the through holes of the first steel pipe segment girder is formed at both ends, and a pair of second steel pipe segment girder arranged on both sides of the first steel pipe segment girder; ; The first steel pipe diaphragm and the pair of second segment girders are tension-settled in a state in which the through holes of the second steel pipe diaphragm are connected to each other, and a compression prestress is introduced into the first steel pipe segment girder. Bonding the first tension material; Provides prestressed girders made of segmented girders, including.

The first steel pipe segment girder and the pair of second steel pipes penetrate the first steel pipe segment girder while the pair of second steel pipe segment girder is disposed on both sides of the first steel pipe segment girder having the steel pipe diaphragm installed at both ends. By tensioning the first tension member connecting the segment girder and introducing compression prestress to the first steel pipe segment girder, the first steel pipe segment girder connects the first steel pipe segment girder and the second steel pipe segment girder while introducing the compression prestress to the first steel pipe segment girder. This is because the process can be performed at one time.

At this time, the first steel pipe segment girder is not necessarily made of only one segment girder, it may be made by the continuous arrangement of two or more steel pipe segment girder depending on the length of the center portion of the bridge.

A third steel pipe diaphragm having a plurality of through holes aligned with at least a portion of the through holes of the first steel pipe segment girder and the second steel pipe segment girder is formed at both ends, and both sides of the pair of second steel pipe segment girder. A pair of third steel pipe segment girder arranged in; The first steel pipe diaphragm and the second steel pipe diaphragm and the through hole of the third steel pipe diaphragm are tension-fixed, and a compression prestress is introduced to the first steel pipe segment girder and the second steel pipe segment girder. It may be configured to further include a second tension material for coupling the pair of second segment girder and the pair of third segment girder, respectively.

As described above, the first steel pipe segment girder positioned at the center of the prestress girder made of the steel pipe segment girder introduces a larger compression prestress and a smaller compression prestress is introduced toward both sides thereof, thereby making the prestress girder manufactured as described above. If the bridge is provided on the bridge, it is possible to more effectively support the load acting largely at the center of the span. In addition, in the prior art, in order to support a load acting largely in the center portion of the span, compression prestress was required to be largely introduced over the entire length of the girder. In addition to the problem of introducing an inefficient prestress, which introduces a large amount of prestress unnecessarily, an excessively large compression prestress is introduced at both ends of the girder, thereby solving the problem of damaging the girder.

At this time, the third steel pipe segment girder also need not necessarily be made of only one steel pipe segment girder, it may be made by two or more steel pipe segment girder are arranged in series.

Similarly, the first tension member serves to connect with the second steel pipe segment girder arranged on both sides while introducing the compression prestress to the first steel pipe segment girder, and the second tension material is a pair of first steel pipe segment girder Compressive prestress is introduced into two-pipe segment girder and serves to connect a pair of third steel pipe segment girder arranged on both sides. However, since both ends of the bridge are mounted on a pier and the like, the tensile stress acts on the lower side of the neutral shaft at the center of the span, so that the first tension member that introduces the compression prestress at the center of the girder to more effectively cancel the tensile stress is the second tension member. Compared to the neutral axis of the first steel pipe segment girder, it is located below.

The steel pipe diaphragm formed at both ends of the steel pipe segment girder extends toward the center of the steel pipe segment girder, and the first tension member arranged through the through hole may be arranged inside the steel pipe segment girder. At this time, the inner circumferential surface of the steel pipe diaphragm extends the inner reinforcement forming a closed curved surface, and a plurality of connection reinforcement connecting the inner reinforcement and the inner wall of the steel pipe segment girder are coupled at intervals in the circumferential direction, the tension material in the steel pipe diaphragm tension Even when settled, tension can be tolerated in the steel pipe diaphragm.

According to another embodiment of the present invention, the steel pipe diaphragm formed at both ends of the steel pipe segment girder is formed extending in the radial direction on the outer side of the steel pipe segment girder, the first tension member arranged through the through hole is the steel pipe It may be arranged outside the segmental girder.

The steel pipe segment girder may be formed in various forms. For convenience of manufacture and aesthetics, when the steel pipe segment girder is formed in a circular shape, the through holes are arranged to be spaced apart from each other along the circumferential direction in the steel pipe diaphragm, and the tension member is disposed in the through holes.

At this time, the through hole may be arranged only below the neutral axis of the steel pipe segment girder, but according to another embodiment of the present invention, the through hole may also be arranged above the neutral axis of the steel pipe segment girder. The tension member arranged in the through hole arranged on the neutral shaft is not tension-fixed in the manufacturing process of the prestress girder synthesized by connecting the steel pipe segment girder, but the bottom plate is synthesized by the bridge girder and the neutral shaft is moved to the upper side of the prestress girder. Tension can settle afterwards. Through this, the tension member installed in the through hole formed in the steel pipe segment girder can be used to introduce the compression prestress as a whole regardless of its position.

On the other hand, when connecting the steel pipe segment girder it is preferred that a sleeve is installed therebetween. The sleeve is composed of a wrapper periphery of the outer circumferential surface of two adjacent steel pipe segment girder and a side plate interposed between the steel pipe segment girder and penetrated by the tension member. Through this, by interconnecting in a state in which the steel pipe segment girder is accommodated inside the periphery, it is possible to facilitate the process of connecting the steel pipe segment girder in the longitudinal direction.

According to another field of the invention, there is provided a method of preparing a first segment girder, comprising: preparing a first segment girder in which a plurality of through holes are longitudinally penetrated and compression prestress is introduced; Preparing a pair of second segment girders formed with a plurality of through holes aligned in a longitudinal direction with at least a portion of the through holes of the first segment girder; After arranging the pair of second segment girder on both sides in the longitudinal direction of the first segment girder, the second tension member is arranged to penetrate the first segment girder and the pair of second segment girder to form the first segment girder. Coupling the first segment girder and the pair of second segment girder while introducing tension pre-stressing the tensioning member into the first segment girder and the pair of second segment girder; It provides a manufacturing method of prestressed girders, characterized in that configured to include.

At this time, the step of preparing a pair of third segment girder formed in the longitudinal direction through the plurality of through holes aligned with at least a portion of the through hole of the first segment girder and the second through hole; After arranging the pair of third segment girder on both sides in the longitudinal direction of the pair of second segment girder, the first segment girder and the pair of second segment girder and the third segment girder Arranging a third tension member to tension-tighten the third tension member to introduce compression prestress into the first segment girder, the pair of second segment girder and the pair of third segment girder, Coupling a segment girder and the pair of third segment girder; It may further include.

In addition, the present invention includes the steps of preparing a first steel pipe segment girder formed with a plurality of through holes penetrated in the longitudinal direction and introduced compression prestress; Preparing a pair of second steel pipe segment girders formed at both ends of a second steel pipe diaphragm having a plurality of through holes aligned with at least a portion of the through holes of the first steel pipe segment girder; After arranging the pair of second steel pipe segment girder on both sides of the first steel pipe segment girder and aligning the through holes, the through holes of the first steel pipe diaphragm and the second steel pipe diaphragm are connected with a first tension member. Coupling the first segment girder and the pair of second segment girder while introducing tension prestress in a state to introduce compression prestress to the first steel tube segment girder; It provides a manufacturing method of a prestressed girder to include.

And preparing a pair of third steel pipe segment girder formed at both ends of a third steel pipe diaphragm having a plurality of through holes aligned with at least a portion of the through holes of the first steel pipe segment girder and the second steel pipe segment girder. ; After arranging the pair of third steel pipe segment girder on both sides of the pair of second steel pipe segment girder and aligning the through holes, the first steel pipe diaphragm, the second steel pipe diaphragm, and the third steel pipe diaphragm are arranged. The pair of second segment girder and the pair of thirds are tension-settled in a state where the through-holes of the second tension member are connected to each other, and compressive prestress is introduced into the first steel tube segment girder and the second steel tube segment girder. Coupling the segment girder; As shown in FIG.

As described above, the present invention, in the production of the prestress girder by connecting the segment girder for the convenience of construction, by the process of connecting the segment girder only in the center portion so as to meet the stress state acting in common in the bridge The large prestress is introduced and the smaller prestress is introduced at both ends, thereby providing a method of manufacturing a bridge prestress girder capable of adjusting the introduction amount of the compression prestress while realizing the convenience of construction and the prestress girder constructed thereby.

That is, the present invention provides a second tension member penetrating the first segment girder and the second segment girder in a state in which a pair of second segment girder is disposed on both sides of the first segment girder where the prestress is introduced by the first tension member. By pre-stressing and introducing the prestress into the first segment girder and the second segment girder together, the first segment girder, which is located in the center of the girder to be synthesized, is subjected to compression prestress by the first tension member and the second tension member. Compression prestress is introduced to the second segment girder located at the outer side of the center only by the second tension member, which is advantageous in that a larger compression prestress can be introduced at the center of the girder while easily making the prestress girder by interconnecting the segment girder. The effect can be obtained.

In addition, the present invention not only solves an inefficient prestress introduction problem in which the prestress is introduced at both ends of the span smaller than at the center, but also introduces an unnecessarily large prestress to both ends, and also excessively large compression prestress at both ends of the girder. The problem that causes the damage to the girder can be solved.

On the other hand, the present invention introduces a larger compression prestress to the center portion of the prestress girder that is finally completed only by the process of connecting the steel pipe segment girder also to the steel pipe segment girder, the smaller compression prestress can be introduced toward both ends of the girder That can achieve the beneficial effect.

Through this, the present invention can easily and quickly produce the prestress girder using the segmental girder, while introducing a compressive prestress corresponding to the stress state acting during common use, more effectively the common load without introducing excessive prestress Will be able to support.

1 is a schematic side view showing the configuration of a prestress girder according to a first embodiment of the present invention;
FIG. 2A is a cross-sectional view taken along the line II-II of FIG. 1
FIG. 2B is a cross-sectional view according to another embodiment conforming to cut line II-II of FIG.
3A to 3C are views showing the configuration according to the manufacturing procedure of the prestress girder of FIG.
Figure 4 is a side cutaway view showing the configuration of the prestress girder according to the second embodiment of the present invention
FIG. 5 is a plan cutaway view of FIG. 4
6 is a cross-sectional view showing the shape of the sleeve of FIG.
7A is a cross-sectional view along the cutting line AA of FIG.
FIG. 7B is a cross-sectional view along the cutting line BB of FIG. 4
FIG. 7C is a cross-sectional view along the cutting line CC of FIG. 4
FIG. 7D is a cross-sectional view along the cutting line EE of FIG. 7B
8 is a perspective view showing a part of the configuration of the connection portion of the prestress girder of FIG.
9 is a view showing a configuration of a tension member installed in the steel pipe diaphragm of FIG.
10A to 10D are views showing the configuration according to the manufacturing procedure of the prestress girder of FIG.
11 is a perspective view showing a part of the configuration of the prestress girder according to the third embodiment similar to FIG.
12 is a cross-sectional view of a pedestrian bridge using the prestress girder of FIG.
Fig. 13 is a conceptual diagram showing a configuration for applying a prestress girder according to the present invention to a continuous bridge.

Hereinafter, the prestress girder 100 according to the first embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail to avoid obscuring the subject matter of the present invention.

As shown in the figure, the prestress girder 100 according to the first embodiment of the present invention is arranged on both sides of the first segment girder 110 and the first segment girder 110, the first segment A pair of second segment girder 120 is connected to the girder 110 in the longitudinal direction, and is arranged on both sides of the pair of second segment girder 120 is connected to the second segment girder 120 in the longitudinal direction A pair of third segment girder 130 and a pair of fourth segment girder 140 are arranged on both sides of the pair of third segment girder 130 and are longitudinally connected to the third segment girder 130. It consists of.

The first segment girder 110 is provided with a through hole in which the first tension member 115 is installed, and a compression prestress is introduced into the first segment girder 110 by the first tension member 115. The first segment girder 110 is formed with a plurality of through holes in addition to the through holes in which the first tension member 115 is installed, and a sheath tube is inserted therein. At this time, the first tension member may be inserted into the through hole to introduce a compression prestress into the first segment girder 110 by a post-tension method, but by pouring concrete to cover the first tension member in a tensioned state, Compression prestress may be introduced to the first segment girder 110 in a tension manner.

Although the first segment girder 110 is illustrated as one segment girder in the drawing, the first segment girder 110 may be made of one segment girder, but may be made of two or more segment girder. That is, since the first segment girder 110 is located at the center of the finally produced prestress girder 100, when the span length of the bridge is sufficiently long, a large number of compression prestresses determined by the design are introduced to the central region. The segment girder may form the first segment girder 110.

The second segment girder 120 has a through hole aligned with the through hole of the first segment girder 110 and is arranged in pairs on both sides of the first segment girder 110. The second tension member 125 is installed in the through hole formed to be aligned with the first segment girder 110 and the second segment girder 120 so that the second tension member 125 is tension-fixed so that the first segment girder 110 is fixed. Compression prestress is introduced into them while interconnecting the pair of second segment girder 120 with each other. Similarly, the second segment girder 120 may be formed of two or more segment girder.

The third segment girder 130 has a through hole aligned with the through hole of the first segment girder 110 and the second segment girder 120 and is arranged in pairs on both sides of the second segment girder 110. The third tension member 135 is installed in the through hole formed to be aligned with the first segment girder 110, the second segment girder 120, and the third segment girder 130, and the third tension member 135 is tension-fixed. As a result, the compression prestress is introduced to the first segment girder 110, the pair of the second segment girder 120, and the third segment girder 130 while interconnecting each other. Similarly, the third segment girder 130 may be formed of two or more segment girder.

The fourth segment girder 140 has a through hole aligned with the through holes of the first segment girder 110, the second segment girder 120, and the third segment girder 130, and both sides of the second segment girder 110. Are arranged in pairs. The fourth tensioning member 145 is installed in the through-holes formed to be aligned with each other in the first segment girder 110 to the fourth segment girder 140 so that the fourth tensioning member 135 is tension-fixed so that the first segment girder 110 ) And a pair of second segment girder 120, the third segment girder 130 and the fourth segment girder 140 are interconnected, and compression prestress is introduced thereto. Similarly, the fourth segment girder 140 may be formed of two or more segment girder.

The through holes formed in the segment girder (110, 120, 130, 140) may be formed so that the tension member (115, 125, 135, 145) can be inserted, respectively, but all the through holes may be formed to be aligned with each other. have. The concave portions 110a are provided at both ends of each segment girder 110, 120, 130, and 140 so that a space for accommodating the configuration 110x for maintaining the fixing state of the tension members 115, 125, 135, and 145 is provided. , 120a, 130a, ..) are provided. After the tension members 115, 125, 135, and 145 have settled, the recesses 110a, 120a, 130a, .. are filled and finished (not shown).

The prestress girder 100 configured as described above is formed by the first tension member 115, the second tension member 125, the third tension member 135, and the fourth tension member 145 in the first segment girder 110 located at the center portion. Compression prestress is introduced, and a compression prestress is introduced by the second tension member 125, the third tension member 135, and the fourth tension member 145 to the second segment girder 120 positioned on the outside thereof. Compression prestress is introduced into the third segment girder 130 located at the outer side by the third tension member 135 and the fourth tension member 145. That is, the largest prestress is introduced into the first segment girder 110 positioned at the center portion of the span where the largest load acts while the girders are installed on the bridge, and progressively smaller prestresses are introduced as farther outwards.

As such, when a larger compression prestress is introduced into the center portion of the girder 100 and a smaller compression prestress is introduced toward the both sides thereof, the prestress girder 100 is installed in the bridge, thereby acting largely at the center of the span. Not only can the load be more effectively supported, but the undesirably large compression prestress is introduced from both ends to introduce a large compression prestress at the center of the span. Can be obtained.

The prestress girder 100 is formed by connecting the segments of the prestressed concrete (PSC) girder, as shown in Figure 2a. Here, the first tension member 115 is used to introduce prestress into the first segment girder 110 located in the center of the prestress girder 100 to which the plurality of segment girders 110, 120, 130, and 140 are connected. In the center portion of the girder, since the tensile stress is largely applied to the lower side of the neutral shaft during common use, the first tension member 115 introducing the compressive prestress to the center portion of the girder to more effectively cancel the tensile stress is the first segment girder 110. Compared to the second tension member 125 that introduces compression prestress into both the second segment girder 120 and the second segment girder 120, the first segment girder 110 may be located at the same height or lower than the neutral axis of the first segment girder 110. Similarly, the second tension member 125 is at the same height or lower than the neutral axis of the segment girder 110, 120, 130, 140 compared to the third tension member 135, and the third tension member 135 is the fourth tension member 135. Compared to the tension member 145 is located at the same height or lower than the neutral axis of the segment girders (110, 120, 130, 140).

Meanwhile, although the prestress girder 100 shown in FIGS. 1 and 2A has been exemplified as a configuration in which a precast concrete segment girder made of concrete as a main material is connected in the longitudinal direction, the prestress girder 100 'according to the present invention is illustrated. As shown in FIG. 2B, the steel girders 110a 'and the steel composite girders composed of the casing concrete 110b' synthesized on the lower flange thereof may be manufactured in the longitudinal direction. Although the cross-sectional view of the I-shaped steel girder and the casing concrete is synthesized in the drawing, the box-shaped steel girder and the casing concrete may be synthesized, and various types of segment girder may be installed in the longitudinal direction.

Hereinafter, the manufacturing method of the prestress girder 100 configured as described above will be described in detail.

Step 1 : As shown in Figure 3a, after the first tension member 115 is inserted into the first through hole 115a of the precast first segment girder 110, which is prepared in advance in a factory, the first tension member ( 115) by pulling it outward (115d) to settle tension. Accordingly, the compression prestress indicated by P1 is introduced into the lower end of the neutral shaft in the first segment girder 110.

Step 2 : Then, as shown in FIG. 3B, after the pair of second segment girder 120 is disposed on both sides of the first segment girder 110, the first segment girder 110 and the second segment are arranged. The second tension member 125 is inserted and installed to penetrate the through-hole penetrating the girder 120 to be aligned. Then, the second tension member 125 is pulled to the outer side 125d to fix the tension. Accordingly, the compression prestress indicated by P2 is introduced into the second segment girder 120 at the lower edge of the neutral shaft, and the sum of P1 and P2 is introduced into the neutral shaft lower edge as the compression prestress to the first segment girder 110.

As such, by connecting the first segment girder 110 and the second segment girder 120 in the longitudinal direction by the second tension member 125, a larger compression prestress is introduced into the first segment girder 110. A smaller compression prestress is introduced into the two segment girder 120.

Step 3 : Then, as shown in FIG. 3C, after the pair of third segment girder 130 is disposed on both sides of the second segment girder 120, the first segment girder 110 and the second segment are arranged. The third tension member 135 is inserted and installed to penetrate the through-holes through which the girder 120 and the third segment girder 130 are aligned. Then, the third tension member 135 is pulled to the outer side 135d to fix the tension. Accordingly, the compressive prestress indicated by P3 is introduced into the third segment girder 130 at the lower edge of the neutral shaft, and the sum of P2 and P3 is introduced into the neutral axis lower margin as the compressed segment of the second segment girder 120, and the first segment girder is At 110, the sum of P1, P2, and P3 is introduced into the lower end of the neutral axis as compression prestress.

By repeating such a method, the compression prestress may be introduced while connecting the fourth segment girder 140 to both sides of the third segment girder 130, thereby manufacturing the prestress girder 100 illustrated in FIG. 1. The prestress girder 100 manufactured using the above method may be manufactured quickly in the field using the segment girder 110, 120, 130, 140, which is manufactured in advance in a factory, etc., and stepwise from both ends of the central part. As a result, it is possible to obtain an advantageous effect of the prestress introduction process and the connecting process in which the compression prestress introduced gradually decreases.

Hereinafter, the prestress girder 200 according to the second embodiment of the present invention will be described in detail with reference to FIGS. 4 to 11. However, in describing the second embodiment of the present invention, detailed descriptions of functions and configurations similar to those of the above-described first embodiment will be omitted to clarify the gist of the present embodiment.

As shown in the figure, the prestress girder 200 according to the second embodiment of the present invention is arranged on both sides of the first steel pipe segment girder 210, the first steel pipe segment girder 210 A pair of second steel pipe segment girder 220 connected in a longitudinal direction with the first steel pipe segment girder 210 and the second steel pipe segment girder 220 are arranged on both sides of the pair of second steel pipe segment girder 220. And a pair of third steel pipe segment girder 230 connected in the longitudinal direction.

4 and 5, the first tension member 215 of the tension members 215, 225, and 235 introduces a compression prestress to the first steel pipe segment girder 210, and a pair of second steel pipe segment girder ( 220) on both sides. The second tension member 225 couples a pair of third steel pipe segment girder 230 to both sides thereof while introducing compression prestress to the first steel pipe segment girder 210 and the second steel pipe segment girder 220. In the drawings, the configuration extending to the third steel pipe segment girder 230 is taken as an example, but additionally, compression prestress may be introduced while the steel pipe segment girder is coupled to both sides.

As shown in the first steel pipe segment girder 210 of FIG. 8 as an example, steel pipe diaphragms 211, 221, and 231 are formed at both ends of each of the steel pipe segment girder 210, 220, and 230, respectively. As shown in 7b, the steel pipe diaphragms 211, 221, and 231 are formed with a plurality of through holes 2111, 2112, 2113, 2114... Through which the tension members 215, 225, and 235 pass.

As shown in FIGS. 7C and 7D, in which the first steel pipe diaphragm 211 of the first steel pipe segment girder 210 is shown as an example, the tension members 215, 225, and 235 are provided in the steel pipe diaphragms 211, 221, and 231. Since it is settled in a tense state, a supporting structure capable of supporting a large force is required. To this end, inner reinforcing members (211a, 221a, ...) forming a closed curved surface is coupled to the inner circumferential surface of each steel pipe diaphragm (211, 221, 231), the inner reinforcing members (211a, 221a, ...) and the steel pipe segment girder ( Connection reinforcing materials (..., 221b, ...) connecting the inner walls (..., 220i ....) of 210, 220, 230, .... are formed with the holes in between.

And, the sleeve 50 shown in Figure 6 is interposed in the connection portion of the steel pipe segment girder (210, 220, 230). The sleeve 50 includes a circumferential portion 51 surrounding both ends of the steel pipe segment girder 210, 220, and 230, and a side plate 52 formed at the center of the circumferential portion 51. As shown in FIG. 7A, the site plate 52 includes through holes 521, 522, which are aligned with the through holes 2111, 2112, 2123, 2114,..., Formed in the steel pipe diaphragms 211, 221, 231. 523, 524, ...) are formed.

The inner circumferential surface 51a of the circumferential portion 51 of the sleeve 50 is accommodated so as to surround the outer circumferential surfaces of both ends of the steel pipe segment girder 210, 220, 230, so that the steel pipe segment girder 210, 220, 230 is in a straight line shape. Assists in longitudinal alignment. When the fabrication of the prestress girder 200 is completed, the circumferential portion 51 of the sleeve 50 may be joined by welding between the outer circumferential surfaces of the steel pipe segment girder 210, 220, and 230.

Although the steel pipe segment girder 210, 220, 230 is shown as one segment girder, the steel pipe segment girder 210, 220, 230 may be formed of two or more segment girder.

Hereinafter, the manufacturing method of the prestress girder 200 configured as described above will be described in detail.

Step 1 : As shown in FIG. 10A, the second steel pipe segment girder 220 is prepared on both sides of the first steel pipe segment girder 210 with the sleeve 50 therebetween.

Step 2 : Then, as shown in FIG. 10B, the two lowermost through holes 2111 of the first steel pipe diaphragm 211 at both ends of the first steel pipe segment girder 210, and the plate 50 of the sleeve 50. Two lower through holes 521 of 52 and one of the lowermost two through holes of the second steel pipe diaphragm 221 at one end of the second steel pipe segment girder 210 in contact with the first steel pipe segment girder 210. The first tension material 215 is disposed to pass through.

That is, as shown in Figure 8, in a state in which a pair of second steel pipe segment girder 220 is placed on both sides of the first steel pipe segment girder 210 in the state ( FIG. 8 is a view illustrating a state in which only a part of the second steel pipe segment girder 220 which contacts the first steel pipe segment girder 210 is cut, and a first tension member, a second tension member, and a third tension member are installed. The lowermost through hole 2111 of the first steel pipe diaphragm 211 of the steel pipe segment girder 210 and the site plate 52 of the sleeve 50 and the second steel pipe diaphragm 221 of the second steel pipe segment girder 220. After placing the first tension member 215 to penetrate through the first tension member 215, the fixing device 70 is installed at both ends of the first tension member 215, so that the first tension member 215 is shown in FIG. To tension in the outward direction 215d and then fixed to the fixing nut 215n.

To this end, an end portion of the first tension member 215 is formed with a male thread, and as the nut 215n engaging with the male thread is fixed on the square plate washer 215p, the first tension member 215 is formed. Tension is maintained. Through this, a pair of second steel pipe segment girder 220 is coupled to both sides of the first steel pipe segment girder 210, respectively, and a compression prestress indicated by P1 is introduced into the first steel pipe segment girder 210.

Step 3 : Then, as shown in Figure 10c, a pair of third steel pipe segment girder 230 with a sleeve 50 between both sides of the pair of second steel pipe segment girder 220 arranged on both sides. ).

Step 4 : Then, as shown in FIG. 10D, the next lowermost through hole 2112 of the second steel pipe diaphragm 221 at both ends of the second steel pipe segment girder 220 and the site plate of the sleeve 50 ( 52, the next lowermost two through holes 522, and one end of the third steel pipe diaphragm 231 in contact with the second steel pipe segment girder 220, and the next lowest two through holes Place the second tension material 225 to pass through the ball. Then, the fixing mechanism 70 is installed at both ends of the second tensioning material 225 to pull the second tensioning material 225 in the outward direction 225d and to be tensioned.

Through this, a pair of third steel pipe segment girder 230 is coupled to both sides of the second steel pipe segment girder 220, respectively, to the first steel pipe segment girder 210 and the second steel pipe segment girder 220 to P2. The indicated compression prestress is additionally introduced. That is, the compression prestress corresponding to the sum of P1 and P2 is introduced into the first steel pipe segment girder 210, and the compression prestress of P2 is introduced into the second steel pipe segment girder 220.

Step 5 : If necessary, the fourth steel pipe segment girder (not shown) may be extended to both sides of the third steel pipe segment girder 230. When the fabrication of the prestress girder 200 is completed, the boundary surface 55 of the outer circumferential surface of the sleeve 50 and the steel pipe segment girder 210, 220, 230 is joined by welding.

However, when fabricating the prestress girder 200, the compression prestress should be introduced to the lower edge of the neutral shaft to effectively support the tensile stresses acting in common, so only the through-holes below the neutral shaft of the steel pipe segment girder 210, 220, 230 may be used. Install tension material to relax. The tension member (295 in FIG. 8) installed in the through holes (2114, 524, ...) located on the upper side of the neutral shaft has a bottom plate synthesized as shown in the sidewalk bridge of FIG. The tension can be settled in the state moved upward of 200.

That is, the through holes 2114, 524,... Located above the neutral axis of the prestress girder 200 itself are synthesized by the bottom plate 30 and the connection part 40 and the welding 40a, and the like. Since it is located below the neutral axis N, the tension member 295 provided in the through-holes 2114, 514, ... is tension-fixed after the composite cross section, so that the tensile stress acting in common of the bridge can be effectively Benefits that can be supported.

Meanwhile, in fabricating the prestress girder 200 using the steel pipe segment girder 210, 220, 230,..., The tension members 215, 225, and 235 are shown in FIGS. Although it may be located inside the steel pipe segment girder (210, 220, 230, ...), according to the third embodiment of the present invention, as shown in Figure 11, the steel pipe diaphragm (311, 321, ...) The tension member 315, 325, 335 is extended to the outside may be located in the outer side of the steel pipe segment girder (310, 320 ...) to be tension-fixed to the outer side (315d, 325d).

Prestress girders (100, 100 ', 200, 300) configured as described above can be produced quickly in the field using a segment girder made in advance in the factory, etc., compression is introduced from the central portion to both ends in step An advantageous effect is achieved in which the prestress introduction process and the connecting process, in which the prestress gradually decreases, consist of one process.

Meanwhile, the prestress girders 100, 100 ', 200, and 300 according to the present invention may be applied to a simple bridge, but may also be applied to a continuous bridge in which the girder continues in the longitudinal direction at the top of the bridge which is the continuous point portion. That is, as shown in Fig. 13, the prestress girder 400I by the above-described method so that the largest compression prestress acts on the span center portion in which the great moment acts large, and the smaller compression prestress acts away from the span center portion. , 400II) by connecting a plurality of segment girders (410, 420, 430), the tension member (435, 445) distributed in the upper edge of the neutral axis of the composite cross-section synthesized the bottom plate in the continuous point portion where the parent moment is large By connecting the pre-stress girders (400I, 400II) adjacent in the longitudinal direction while introducing the compression prestress on the neutral axis by, it can be used to construct the bridge through the girders (400I, 400II) continuous to the piers or alternations.

Here, the process of connecting the longitudinally adjacent prestress girders 400I and 400II may be performed at the top of the piers. Further, in the continuous point portion, the tension members 435 and 445 are distributed at the upper edge of the neutral shaft. In the case of the concrete beam, the tension tubes 435 and 445 are separately installed in advance in the case of the concrete beam. 445 may be installed, and in the case of a steel pipe girder, tension members 435 and 445 may be installed in the through hole located above the diaphragm. Although two span bridges are illustrated in the drawings, it is apparent to those skilled in the art that the above configuration can be applied to two or more span continuous bridges.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. That is, in the illustrated drawings, the compression prestress is introduced into the segmental girder in two or four stages to produce the prestressed girders 100 and 200, but each of these segmental girders may be made of two or more segmental girders. Compression prestress is introduced in fewer steps, and longitudinally connected prestress girders can be manufactured. In addition, compression prestress is introduced in more steps, and interconnected prestress girders can be fabricated. In addition, although the cross section of the steel pipe segment girder is illustrated as an example in the drawing, it may be configured as a steel pipe segment girder having a cross section of various shapes such as a square cross section.

100, 100 ', 200, 300: prestressed girder 110: first segment girder
115, 215: First tension member 120: Second segment girder
125, 225: 2nd tension member 130: 3rd segment girder
135: third tension material 140: fourth segment girder
210: first steel pipe segment girder 211: first steel pipe diaphragm
220: second steel pipe segment girder 221: second steel pipe diaphragm
230: third steel pipe segment girder 231: third steel pipe diaphragm
50: sleeve 51: circumference
52: site plate

Claims (21)

A first steel pipe segment girder having a first steel pipe diaphragm having a plurality of through holes penetrated therein;
A second steel pipe diaphragm having a plurality of through holes formed in alignment with at least a part of the through holes of the first steel pipe segment girder is formed at both ends, and a pair of second steel pipe segment girder arranged on both sides of the first steel pipe segment girder; ;
The first steel pipe segment girder and the pair of second steel pipe segments are tension-fixed in a state in which the through-holes of the first steel pipe diaphragm and the second steel pipe diaphragm are connected, and a compression prestress is introduced into the first steel pipe segment girder. A first tension member for joining the girder;
Prestressed girders made of segmented girders, including.
The method of claim 1,
The first steel pipe segment girder is prestressed girders made of segmented girders, characterized in that consisting of two or more steel pipe segment girder.
The method of claim 1,
A third steel pipe diaphragm having a plurality of through-holes aligned with at least a portion of the through-holes of the first steel pipe segment girder and the second steel pipe segment girder is formed at both ends, and arranged on both sides of the pair of second steel pipe segment girder. A pair of third steel pipe segment girder;
The first steel pipe diaphragm and the second steel pipe diaphragm and the through hole of the third steel pipe diaphragm are tension-fixed, and a compression prestress is introduced to the first steel pipe segment girder and the second steel pipe segment girder. A second tension member for coupling the pair of second steel pipe segment girder and the pair of third steel pipe segment girder, respectively;
Prestressed girders made of additionally included segmental girders.
The method of claim 3, wherein
The first tension member is a prestress girder made of segment girder, characterized in that spaced further downward from the neutral axis of the first steel pipe segment girder than the second tension member.
5. The method according to any one of claims 1 to 4,
The through hole is formed to extend into the inner side of the steel pipe segment girder prestress girders made of segment girder, characterized in that the first tension member is arranged inside the steel pipe segment girder.
5. The method according to any one of claims 1 to 4,
Two or more prestress girders are used in a continuous bridge by connecting two or more in the longitudinal direction, and tension-tightening tension members arranged above the neutral axis in the longitudinal connection portions of the prestress girders corresponding to the positions of the continuous points of the continuous bridges. A prestress girder, wherein the prestress is introduced above the neutral axis while connecting the prestress girder in the longitudinal direction.
5. The method according to any one of claims 1 to 4,
The through-hole is formed to extend to the outside of the steel pipe segment girder prestress girders made of segment girder, characterized in that the first tension member is arranged on the outside of the steel pipe girder.
5. The method according to any one of claims 1 to 4,
The steel pipe segment girder is formed in a circular shape, and the through holes are spaced apart from each other along the circumferential direction;
The through hole is also formed in the steel pipe diaphragm above the neutral axis of the steel pipe segment girder, the tension material installed in the through hole located above the neutral shaft is tension-fixed after the bottom plate is synthesized in the bridge girder Prestressed girders made of segmented girders.
5. The method according to any one of claims 1 to 4,
A prestress girder made of a segmental girder, characterized in that a circumferential portion of the outer circumferential surface of two adjacent steel pipe segment girder and a sleeve formed between the steel pipe segment girder and a side plate through which a tension member penetrates are installed.
Preparing a first steel pipe segment girder in which a plurality of through holes are formed through the first steel pipe diaphragm and the compression prestress is introduced;
Preparing a pair of second steel pipe segment girders formed at both ends of a second steel pipe diaphragm having a plurality of through holes aligned with at least a portion of the through holes of the first steel pipe segment girder;
After arranging the pair of second steel pipe segment girder on both sides of the first steel pipe segment girder and aligning the through holes, the through holes of the first steel pipe diaphragm and the second steel pipe diaphragm are connected with a first tension member. Coupling the first steel pipe segment girder and the pair of second steel pipe segment girder while introducing tension pre-stress into the first steel pipe segment girder;
How to make prestressed girders to include.
The method of claim 10,
Preparing a pair of third steel pipe segment girder formed at both ends of a third steel pipe diaphragm having a plurality of through holes aligned with at least a portion of the through holes of the first steel pipe segment girder and the second steel pipe segment girder;
After arranging the pair of third steel pipe segment girder on both sides of the pair of second steel pipe segment girder and aligning the through holes, the first steel pipe diaphragm, the second steel pipe diaphragm, and the third steel pipe diaphragm are arranged. The pair of second steel pipe segment girder and the pair of first and tension settled in the state connected to the through hole of the second tension member, and the compression prestress is introduced into the first steel pipe segment girder and the second steel pipe segment girder Coupling the three steel pipe segment girder;
The production method of the prestressed girder which includes more. delete delete delete delete delete delete delete delete delete delete

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